Complex YOLOv4
The PyTorch Implementation based on YOLOv4 of the paper: Complex-YOLO: Real-time 3D Object Detection on Point Clouds
Features
-
Realtime 3D object detection based on YOLOv4
-
Tensorboard
-
Mosaic/Cutout augmentation for training
-
Use GIoU loss of rotated boxes for optimization.
-
Update 2020.08.26: Super Fast and Accurate 3D Object Detection based on 3D LiDAR Point Clouds
-
Faster training, faster inference
-
An Anchor-free approach
-
No need for Non-Max-Suppression
-
Demonstration (on a GTX 1080Ti)
-
2. Getting Started
2.1. Requirement
pip install -U -r requirements.txt
For mayavi
and shapely
libraries, please refer to the installation instructions from their official websites.
2.2. Data Preparation
Download the 3D KITTI detection dataset from here.
The downloaded data includes:
- Velodyne point clouds (29 GB): input data to the Complex-YOLO model
- Training labels of object data set (5 MB): input label to the Complex-YOLO model
- Camera calibration matrices of object data set (16 MB): for visualization of predictions
- Left color images of object data set (12 GB): for visualization of predictions
Please make sure that you construct the source code & dataset directories structure as below.
For 3D point cloud preprocessing, please refer to the previous works:
2.3. Complex-YOLO architecture
This work has been based on the paper YOLOv4: Optimal Speed and Accuracy of Object Detection.
Please refer to several implementations of YOLOv4 using PyTorch DL framework:
- Tianxiaomo/pytorch-YOLOv4
- Ultralytics/yolov3_and_v4
- WongKinYiu/PyTorch_YOLOv4
- VCasecnikovs/Yet-Another-YOLOv4-Pytorch
2.4. How to run
2.4.1. Visualize the dataset (both BEV images from LiDAR and camera images)
cd src/data_process
- To visualize BEV maps and camera images (with 3D boxes), let's execute (the
output-width
param can be changed to show the images in a bigger/smaller window):
python kitti_dataloader.py --output-width 608
- To visualize mosaics that are composed from 4 BEV maps (Using during training only), let's execute:
python kitti_dataloader.py --show-train-data --mosaic --output-width 608
By default, there is no padding for the output mosaics, the feature could be activated by executing:
python kitti_dataloader.py --show-train-data --mosaic --random-padding --output-width 608
- To visualize cutout augmentation, let's execute:
python kitti_dataloader.py --show-train-data --cutout_prob 1. --cutout_nholes 1 --cutout_fill_value 1. --cutout_ratio 0.3 --output-width 608
2.4.2. Inference
Download the trained model from here,
then put it to ${ROOT}/checkpoints/
and execute:
python test.py --gpu_idx 0 --pretrained_path ../checkpoints/complex_yolov4/complex_yolov4_mse_loss.pth --cfgfile ./config/cfg/complex_yolov4.cfg --show_image
2.4.3. Evaluation
python evaluate.py --gpu_idx 0 --pretrained_path <PATH> --cfgfile <CFG> --img_size <SIZE> --conf-thresh <THRESH> --nms-thresh <THRESH> --iou-thresh <THRESH>
(The conf-thresh
, nms-thresh
, and iou-thresh
params can be adjusted. By default, these params have been set to 0.5)
2.4.4. Training
2.4.4.1. Single machine, single gpu
python train.py --gpu_idx 0 --batch_size <N> --num_workers <N>...
2.4.4.2. Multi-processing Distributed Data Parallel Training
We should always use the nccl
backend for multi-processing distributed training since it currently provides the best
distributed training performance.
- Single machine (node), multiple GPUs
python train.py --dist-url 'tcp://127.0.0.1:29500' --dist-backend 'nccl' --multiprocessing-distributed --world-size 1 --rank 0
- Two machines (two nodes), multiple GPUs
First machine
python train.py --dist-url 'tcp://IP_OF_NODE1:FREEPORT' --dist-backend 'nccl' --multiprocessing-distributed --world-size 2 --rank 0
Second machine
python train.py --dist-url 'tcp://IP_OF_NODE2:FREEPORT' --dist-backend 'nccl' --multiprocessing-distributed --world-size 2 --rank 1
To reproduce the results, you can run the bash shell script
./train.sh
Tensorboard
- To track the training progress, go to the
logs/
folder and
cd logs/<saved_fn>/tensorboard/
tensorboard --logdir=./
- Then go to http://localhost:6006/:
2.5. List of usage for Bag of Freebies (BoF) & Bag of Specials (BoS) in this implementation
Backbone | Detector | |
---|---|---|
BoF | [x] Dropblock [x] Random rescale, rotation (global) [x] Mosaic/Cutout augmentation |
[x] Cross mini-Batch Normalization [x] Dropblock [x] Random training shapes |
BoS | [x] Mish activation [x] Cross-stage partial connections (CSP) [x] Multi-input weighted residual connections (MiWRC) |
[x] Mish activation [x] SPP-block [x] SAM-block [x] PAN path-aggregation block [x] GIoU loss [ ] CIoU loss |
Contact
If you think this work is useful, please give me a star!
If you find any errors or have any suggestions, please contact me (Email: [email protected]
).
Thank you!
Citation
@article{Complex-YOLO,
author = {Martin Simon, Stefan Milz, Karl Amende, Horst-Michael Gross},
title = {Complex-YOLO: Real-time 3D Object Detection on Point Clouds},
year = {2018},
journal = {arXiv},
}
@article{YOLOv4,
author = {Alexey Bochkovskiy, Chien-Yao Wang, Hong-Yuan Mark Liao},
title = {YOLOv4: Optimal Speed and Accuracy of Object Detection},
year = {2020},
journal = {arXiv},
}
Folder structure
${ROOT}
└── checkpoints/
├── complex_yolov3/
└── complex_yolov4/
└── dataset/
└── kitti/
├──ImageSets/
│ ├── train.txt
│ └── val.txt
├── training/
│ ├── image_2/ <-- for visualization
│ ├── calib/
│ ├── label_2/
│ └── velodyne/
└── testing/
│ ├── image_2/ <-- for visualization
│ ├── calib/
│ └── velodyne/
└── classes_names.txt
└── src/
├── config/
├── cfg/
│  ├── complex_yolov3.cfg
│  ├── complex_yolov3_tiny.cfg
│  ├── complex_yolov4.cfg
│  ├── complex_yolov4_tiny.cfg
│  ├── train_config.py
│  └── kitti_config.py
├── data_process/
│  ├── kitti_bev_utils.py
│  ├── kitti_dataloader.py
│  ├── kitti_dataset.py
│  ├── kitti_data_utils.py
│  ├── train_val_split.py
│  └── transformation.py
├── models/
│  ├── darknet2pytorch.py
│  ├── darknet_utils.py
│  ├── model_utils.py
│  ├── yolo_layer.py
└── utils/
│ ├── evaluation_utils.py
│ ├── iou_utils.py
│ ├── logger.py
│ ├── misc.py
│ ├── torch_utils.py
│ ├── train_utils.py
│ └── visualization_utils.py
├── evaluate.py
├── test.py
├── test.sh
├── train.py
└── train.sh
├── README.md
└── requirements.txt
Usage
usage: train.py [-h] [--seed SEED] [--saved_fn FN] [--working-dir PATH]
[-a ARCH] [--cfgfile PATH] [--pretrained_path PATH]
[--img_size IMG_SIZE] [--hflip_prob HFLIP_PROB]
[--cutout_prob CUTOUT_PROB] [--cutout_nholes CUTOUT_NHOLES]
[--cutout_ratio CUTOUT_RATIO]
[--cutout_fill_value CUTOUT_FILL_VALUE]
[--multiscale_training] [--mosaic] [--random-padding]
[--no-val] [--num_samples NUM_SAMPLES]
[--num_workers NUM_WORKERS] [--batch_size BATCH_SIZE]
[--print_freq N] [--tensorboard_freq N] [--checkpoint_freq N]
[--start_epoch N] [--num_epochs N] [--lr_type LR_TYPE]
[--lr LR] [--minimum_lr MIN_LR] [--momentum M] [-wd WD]
[--optimizer_type OPTIMIZER] [--burn_in N]
[--steps [STEPS [STEPS ...]]] [--world-size N] [--rank N]
[--dist-url DIST_URL] [--dist-backend DIST_BACKEND]
[--gpu_idx GPU_IDX] [--no_cuda]
[--multiprocessing-distributed] [--evaluate]
[--resume_path PATH] [--conf-thresh CONF_THRESH]
[--nms-thresh NMS_THRESH] [--iou-thresh IOU_THRESH]
The Implementation of Complex YOLOv4
optional arguments:
-h, --help show this help message and exit
--seed SEED re-produce the results with seed random
--saved_fn FN The name using for saving logs, models,...
--working-dir PATH The ROOT working directory
-a ARCH, --arch ARCH The name of the model architecture
--cfgfile PATH The path for cfgfile (only for darknet)
--pretrained_path PATH
the path of the pretrained checkpoint
--img_size IMG_SIZE the size of input image
--hflip_prob HFLIP_PROB
The probability of horizontal flip
--cutout_prob CUTOUT_PROB
The probability of cutout augmentation
--cutout_nholes CUTOUT_NHOLES
The number of cutout area
--cutout_ratio CUTOUT_RATIO
The max ratio of the cutout area
--cutout_fill_value CUTOUT_FILL_VALUE
The fill value in the cut out area, default 0. (black)
--multiscale_training
If true, use scaling data for training
--mosaic If true, compose training samples as mosaics
--random-padding If true, random padding if using mosaic augmentation
--no-val If true, dont evaluate the model on the val set
--num_samples NUM_SAMPLES
Take a subset of the dataset to run and debug
--num_workers NUM_WORKERS
Number of threads for loading data
--batch_size BATCH_SIZE
mini-batch size (default: 4), this is the totalbatch
size of all GPUs on the current node when usingData
Parallel or Distributed Data Parallel
--print_freq N print frequency (default: 50)
--tensorboard_freq N frequency of saving tensorboard (default: 20)
--checkpoint_freq N frequency of saving checkpoints (default: 2)
--start_epoch N the starting epoch
--num_epochs N number of total epochs to run
--lr_type LR_TYPE the type of learning rate scheduler (cosin or
multi_step)
--lr LR initial learning rate
--minimum_lr MIN_LR minimum learning rate during training
--momentum M momentum
-wd WD, --weight_decay WD
weight decay (default: 1e-6)
--optimizer_type OPTIMIZER
the type of optimizer, it can be sgd or adam
--burn_in N number of burn in step
--steps [STEPS [STEPS ...]]
number of burn in step
--world-size N number of nodes for distributed training
--rank N node rank for distributed training
--dist-url DIST_URL url used to set up distributed training
--dist-backend DIST_BACKEND
distributed backend
--gpu_idx GPU_IDX GPU index to use.
--no_cuda If true, cuda is not used.
--multiprocessing-distributed
Use multi-processing distributed training to launch N
processes per node, which has N GPUs. This is the
fastest way to use PyTorch for either single node or
multi node data parallel training
--evaluate only evaluate the model, not training
--resume_path PATH the path of the resumed checkpoint
--conf-thresh CONF_THRESH
for evaluation - the threshold for class conf
--nms-thresh NMS_THRESH
for evaluation - the threshold for nms
--iou-thresh IOU_THRESH
for evaluation - the threshold for IoU